Cardiology

Question 1

Definition of heart failure?

Answer 1

Failure of the body to maintain a cardiac output that can accommodate metabolic demands.

Question 2

5 main causes of heart failure?

Answer 2

Coronary artery disease
Hypertension
Valvular heart disease
Cardiomyopathy
Cor Pulmonale

Question 3

How to calculate Cardiac Output?

Answer 3

Heart Rate x Stroke Volume

Question 4

Three main components of the neurohormonal component of cardiovascular regulation?

Answer 4

RAAS system
Sympathetic nervous system
Vasopressin (ADH)

Question 5

Role of the sympathetic nervous system in Heart Failure?

Answer 5

Increased cardiac sympathetic activity activates β₁ β₂ and α₁ leads to increased cardiac toxicity and arrhythmias.

Increased sympathetic activity to the kidneys leads to stimulation of α₁, and β₁ (Leading to activation of RAAS) Increased BP

Question 6

What is hBNP?

Answer 6

Brain Natriuretic Peptide

Predominantly found in cardiac ventricles

vasodilatory and Diuretic properties.

Question 7

Effects of hBNP?

Answer 7

Dilation of veins and arteries

Decreased Noradrenaline and aldosterone

Increased Diuresis & Natriuresis

Question 8

Some endothelium derived Vasodilators?

Answer 8

NO

Bradykinin

Prostacyclin

Question 9

Endothelium derived vasoconstrictor?

Answer 9

Endothelin I

Question 10

Symptoms (NOT SIGNS) of Left Ventricular Failure?

Answer 10

Dyspnoea on exertion

Nocturnal Dyspnoea

Orthopnoea (SOB when lying flat)

Cough

Haemoptysis (coughing up blood)

Question 11

Signs (NOT SYMPTOMS) of Left ventricular

Answer 11

Basal Lung Crackles

Tachycardia

S3 Gallop (heart sound)

Pleural effusion

Question 12

Right ventricular failure Symptoms (not signs)?

Answer 12

Abdominal pain

Anorexia

Nausea

Bloating

swelling

Question 13

Right Ventricular failure Signs (not symptoms)?

Answer 13

Peripheral oedema

Jugular venous distension

Hepato-jugular reflex

Hepatomegaly

Ascites

Question 14

Class I, II, II and IV classifications of heart failure?

Answer 14

I: No symptoms with ordinary activity

II: Slight limitation with physical activity

III: Marked limitation with physical activity

IV: Unable to carry out any physical activity with discomfort, symptoms may be present at rest.

Question 15

5 year mortality rate after heart failure diagnosis?

Answer 15

50%

Question 16

Diagnostic techniques used to evaluate New onset heart failure?

Answer 16

ECG

Chest X-Ray

Blood-Test

Echocardiography

Question 17

Uses of Diuretics in heart failure?

Answer 17

Used to Relieve fluid retention

Decrease Bloop Pressure

Improved exercise tolerance

Facilitate the use of other drugs used for heart failure

Question 18

Drugs to use in Heart failure?

Answer 18

Diuretics

ACE inhibitors

Angiotensin Receptor Blockers

Beta-Blockers

Aldosterone antagonists

Digitalis Glycosides

Question 19

What is automaticity in pacemaker cells?

Answer 19

A pacemakers cell’s ability to spontaneously depolarise, and propagate an Action potential.

Question 20

Where do sympathetic and parasympathetic innervation act in the heart?

Answer 20

SA node, pretty much no effect on lower pacemakers.

Question 21

What are the three pacemakers of the heart?

Answer 21

SA node (normal)
- 60-100 min-1

AV node
- 40-60 min-1

Purkinje fibres
- 20-40 min-1

Question 22

Three main mechanisms leading to the generation of arrhythmias?

Answer 22

Enhanced automaticity

Re-Entry

After depolarisation

Question 23

How can enhanced automaticity generate an arrhythmia?

Answer 23

If a lower pacemaker becomes faster than a higher pacemaker then this one will start to take over and the heart will not contract rhythmically.

Question 24

How can re-entry generate an arrhythmia?

Answer 24

1. Slow conduction causes a short refractory period and this means the myocyte is able to receive new impulses
2. There is rapid conduction and a long refractory period meaning the myocyte cannot receive new impulses

If there are two pathways next to each other firstly the beat cannot gain entry to the rapid conduction pathway as it has not recover and so will travel down the slow one, when it reaches the end of the slow it can now travel back up the rapid one and will cause a circular pathway of contraction.

Question 25

Examples of re-entry arrhythmias?

Answer 25

Macro-reentry: Wolf-Parkinson White

Micro-reentry: Atrial fibrillation

Question 26

What can arrhythmias present with?

Answer 26

Syncope (blackouts)
Palpitations
Angina
Dyspnoea

Question 27

What four things do you use to clinically classify arrhythmias?

Answer 27

Heart rate (tchy/bradycardic)
Rhythm (regular/irregular)
Site (supraventricular/ventricular)
QRS complex of an ECG (narrow/broad)

Question 28

How can you tell whether an arrhythmia is supraventricular or ventricular?

Answer 28

Supraventricular if the QRS is narrow.

Question 29

Types of atrial ectopic beats?

Answer 29

Isolated ectopic beat

Atrial tachycardia

Atrial flutter (atria not really beating)

Atrial fibrillation (atria not contracting at all)

Question 30

What does it mean in an ECG if the p-wave is negative?

Answer 30

That the AV node is depolarising from the bottom up

Question 31

Examples of ventricular ectopic beats?

Answer 31

Ventricular tachycardia

Ventricular fibrillation (dead unless defibrillated)

Heart block

Question 32

Types of heart Block?

Answer 32

First Degree: AV node very slow to conduct resulting in very long PR interval

Second degree:

• Mobitz I: Some P waves are generated but not conducted
• Mobitz II: This is pathological, not every P-wave is conducted but there is a rhythm to which ones are and a set PR interval.

Third degree heart block: No conduction to ventricles at all, the purkinje fibres become the pacemakers

Question 33

What’s asystole?

Answer 33

No heart contraction.

Question 34

Four main anti-arrhythmic drug classes?

Answer 34

Sodium channel blockers
Beta adrenoceptor blockers
Potassium channel blockers
Calcium channel blockers

Question 35

Mechanism of action of beta-adrenoceptor blockers?

Answer 35

Suppression of abnormal pacemakers

Question 36

Mechanism of action of potassium channel blockers?

Answer 36

Tissue remains in refractory period for longer

Question 37

Mechanism of calcium-channel blockers?

Answer 37

Decrease automaticity in supraventricular tissues.

Question 38

5 things to look out for during a CV examination, when measuring someone’s pulse?

Answer 38

Volume
Rate
Character
Rhythm
Quality

Question 39

What are the changes to the ECG in a STEMI?

Answer 39

ST elevation

Deep Q wave

Negative T wave in late STEMI